KR20030027607A - Method for transmitting a packet data communication system - Google Patents

Abstract

PURPOSE: A method of transmitting packet data in a communication system is provided to determine priorities of control channels, and to transmit control information for transmitted packet data through the control channels, then to transmit the packet data, thereby improving resource efficiency in CDM(Code Division Multiplexing)/TDM(Time Division Multiplexing) systems. CONSTITUTION: A mobile communication system determines priorities of control channels for receiving data. The system transmits control information on transmitted packet data through the control channels. The system transmits the packet data through transmission channels corresponding to the control channels. The system supplies information on whether to support a CDM, the number of maximum usable control channels, the number of currently-used channels, and whether to use the CDM to terminals. The system monitors the control channels by using the supplied information. The system receives data on channels transmitted to a self by using a monitored result.

Description

Method for transmitting a packet data communication system

The present invention relates to a mobile communication system, and more particularly, to a method of transmitting packet data.

Conventional wireless communication systems for packet data transmission use a physical channel such as a packet data channel (PDCH) and a packet data control channel (PDCCH) for packet data transmission.

The PDCH is actually a channel for transmitting packet data to be transmitted to the corresponding terminal (or user, hereinafter referred to as terminal). Several users divide the PDCH by using Time Division Multiplexing (TDM) or divide the PDCH by Code Division Multiplexing (hereinafter, referred to as CDM). Alternatively, the TDM scheme and the CDM scheme may be mixed.

The PDCCH includes control information that enables the terminal to properly receive data transmitted through the PDCH without error. One or more such control channels may be used in addition to the PDCCH.

In the method of transmitting the data by the base station to each terminal by TDM method and CDM method, packet data transmitted to each terminal is transmitted on different time axes or different on the same time axis. Is sent using the code. Here, the code distinguishes data of respective terminals, and a representative example is a Walsh code having excellent orthogonality.

In the TDM scheme, the packet data transmitted to each terminal always uses all available resources allocated to the PDCH channel. As a result, even if only a part of the available resources is needed, the use of all of them may result in waste of resources.

In addition, in the CDM / TDM scheme, the length of the PDCH's time axis is always fixed for all terminals, which leads to many limitations in the efficient use of resources, and heavy use of PDCCHs used for one PDCH. There is a difficulty in utilizing efficient system resources.

Accordingly, the present invention has been made in view of the above-mentioned problems of the prior art, and is to provide a method of transmitting packet data for improving resource utilization efficiency in a CDM / TDM scheme.

According to an aspect of the present invention for achieving the above object, in a mobile communication system in which a time division scheme and a code division scheme are mixed, determining priorities of control channels for data reception of terminals; Transmitting control information on packet data to be transmitted through the determined priority control channel; And transmitting the packet data through a transmission channel corresponding to the control channel.

Preferably, the method may further include providing information about whether the code multiplexing scheme is supported, the maximum number of control channels available, the number of control channels currently being used, and whether the code multiplexing scheme is used.

Preferably, monitoring the control channels using the provided information; The method may further include receiving data of a channel transmitted to the using the monitoring result.

Preferably, the specific bit of the number of control channels currently being used indicates whether to use code multiplexing.

Advantageously, Walsh code configuration information of the transport channels as much as the maximum number of available control channels and priority information of the control channels are further included. In this case, the Walsh code configuration information is transmitted to terminals through the control channel or a newly defined control channel.

According to another aspect of the present invention for achieving the above object, in the mobile communication system that the time division scheme and the code division scheme are mixed, scheduling the packets to be transmitted; Determining whether to perform code multiplexing at the scheduling time; As a result of the determination, when performing code multiplexing, sequentially transmitting control information of packets to be code multiplexed to control channels having priority; And transmitting the scheduled packets through transport channels corresponding to the control channels having the priority.

Preferably, if the code multiplexing is not performed as a result of the determination, the method further includes the step of transmitting the control information via a specific control channel.

Preferably, as a result of the determination, when code multiplexing is not performed, the transport channels transmit packets using all Walsh codes. In this case, each transmission unit time of the transmission channels is limited to a specific length.

Advantageously, each transmission unit time of said transmission channels is smaller, or smaller and uniform than a reference transmission channel.

According to another aspect of the present invention for achieving the above object, in a mobile communication system in which a time division scheme and a code division scheme are mixed, priority information of control channels for data reception from the system side, Receiving usage information and code multiplexing information; Monitoring, by the terminal, the control channels according to the information; And receiving the data of the channel transmitted to the terminal according to the monitoring result.

Preferably, the control channel usage information includes the maximum number of control channels available in the system and the number of control channels currently being used.

Preferably, if the terminal has not received the code multiplexing availability information, or if the code multiplexing is not used in the system, and if the terminal knows the maximum number of control channels, the maximum number of transmission channels To monitor the control channels.

Preferably, when the terminal receives the code multiplexing availability information and knows the maximum number of control channels, the terminal monitors the control channels according to the availability information.

Preferably, if code multiplexing is used above, the terminal monitors all control channels.

Preferably, if code multiplexing is not used above, the terminal monitors only a particular control channel.

Preferably, if the code multiplexing information is not used and the terminal knows the number of control channels currently being used, the number of control channels is monitored as much as the number of control channels.

Preferably, the control channel is monitored until it knows that there is data being received at the terminal or that all Walsh codes have been used.

1 is a diagram illustrating an example of a TDM packet transmission used in the present invention.

2 is a diagram showing an example of a packet transmission of the CDM / TDM scheme used in the present invention.

3 is a diagram illustrating an example of a CDM / TDM scheme according to the present invention;

4a to 4b are diagrams showing another example of a CDM / TDM scheme according to the present invention.

5a to 5c are diagrams showing another example of a CDM / TDM scheme according to the present invention.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

Prior to describing the present invention, the parameters used in the present invention are described below.

In the present invention, the aforementioned Walsh code, PDCH, and PDCCH are used. Here, the Walsh codes, PDCH, and PDCCHs are not limited to the names, but represent codes or channels having the same function. In addition, a newly defined physical channel NPDCCH (hereinafter referred to as NPDCCH) is used to additionally transmit control information not included in the conventional control channel.

The Walsh code space is a collection of Walsh codes currently available when the base station transmits packet data. The components change over time.

Walsh_Max is the maximum number of Walsh codes that can be included in the Walsh code space, and the value changes over time.

Walsh (all) is a parameter indicating all Walsh codes in the Walsh code space.

PDCH (i) means the i-th PDCH when it is possible to use two or more PDCHs. In this case, each PDCH uses Walsh codes in Walsh code space separately.

For example, if up to four PDCHs are available in a system, PDCH (0), PDCH (1), PDCH (2), PDCH (3) are possible, and PDCH scheduled to transmit packet data at some point in time They share the Walsh code space. However, if only one PDCH is scheduled, the PDCH uses Walsh (all). On the other hand, when PDCH (0) and PDCH (3) are used at the same time, these two PDCHs divide Walsh code space, and the Walsh codes they use are defined as Walsh (0) and Walsh (3), respectively.

Walsh (i) is a set of Walsh codes used by PDCH (i) at a specific transmission time. This element consists of elements in the Walsh code space. Although the Walsh code space does not change, the Walsh code belonging to Walsh (i) changes over time. That is, Walsh (i) of the previous time and Walsh (i) of the current time have different constituent elements and number of elements. The Walsh code usage unit of Walsh (i) is x, and the number of elements of each Walsh (i) is a multiple of x. 1x, 2x, 3x, etc. The number of elements in Walsh (i) is independent of the number of Walsh (all).

N _{max_PDCH} is the maximum number of PDCH or PDCCH that the system or sector can use.

N _{real_PDCH} is the number of PDCH or PDCCH that the system or sector uses at a given time.

As shown in FIG. 1, the TDM packet data is transmitted by a base station in a time division manner by determining the order of data to be transmitted to each terminal. Here, the base station always uses all Walsh code space for the PDCH.

In FIG. 1, the length of time of the transmission unit on the PDCH and the PDCCH is fixed or variable. In addition, the transmission unit time lengths of the PDCH and the PDCCH do not necessarily have to match. user k implies packet data or control information for user k (or terminal k). Transmission of the PDCH and PDCCH for the user k is determined according to a specific rule, the transmission time and the transmission length. Here, the time interval between transmission of PDCH and PDCCH for each user may or may not exist depending on the system environment.

In the CDM / TDM packet data transmission, as shown in FIG. 2, the base station determines the order of data to be transmitted to each terminal (scheduling), and transmits the data in the time division (TDM) and code division (CDM) methods. In this manner, only one PDCH may be transmitted at a time of transmission, and several PDCHs may be transmitted.

When one PDCH is transmitted, Walsh (all) is used for this PDCH. When two or more PDCHs are transmitted, each PDCH uses Walsh codes in Walsh code spaces separately. That is, each PDCH (i) uses Walsh (i). PDCH (i) has PDCCH (i) which is a PDCCH having control information corresponding to each.

The terminal monitors the PDCCH (i), finds out what form of packet data is transmitted through which PDCH (i), and can receive the corresponding information. The transmission unit time lengths of the PDCH (i) and the PDCCH (i) do not necessarily need to match.

2 shows an example of a case where up to four PDCHs may exist in the CDM / TDM scheme. Here, the time lengths of the transmission units on the PDCH (i) and the PDCCH (i) are fixed or variable. There may or may not be a time interval between transmissions of PDCH or PDCCH for each user. In FIG. 2, the empty space is a case where PDCH or PDCCH is not used. In the transmission period (a), four PDCH (i) are transmitted, and four PDCCH (i) are used. In the transmission period (b), three PDCH (i) are transmitted, and three PDCCH (i) are used. In the transmission period (c), three PDCH (i) are transmitted, and three PDCCH (i) are used. In the transmission period (d), one PDCH (i) is transmitted and one PDCCH (i) is used. In the transmission period (e), four PDCH (i) are transmitted, and four PDCCH (i) are used.

In order to operate the TDM or CDM / TDM scheme of FIGS. 1 and 2, the present invention informs terminals (or respective terminals) of the following information.

First, the base station informs the terminals (or each terminal) whether the CDM is supported. Whether this is supported tells the terminals by physical channel, signaling method, broadcast method, and the like. At this time, the base station informs the terminals from time to time according to its first operation or system operation.

Second, the base station determines the maximum number of available PDCCH N _{max_PDCH} . The N _{max_PDCH} information is a fixed value of the system or a value that informs the terminals by using a physical channel, a signaling method, or a broadcasting method. At this time, the base station informs the terminals from time to time according to its first operation or system operation.

Third, the base station informs the terminals of the configuration information of Walsh codes for these N _{max_PDCH} PDCHs and the priority of PDCCHs together with the N _{max_PDCH} information. The Walsh code configuration information and priority information of the PDCCH are fixed values of the system or values that are informed by a physical channel, a signaling method, or a broadcasting method. At this time, the base station informs the terminals from time to time according to its first operation or system operation. Each PDCCH (i) has priority in order according to importance. Here, it is assumed that the priority of PDCCH (i) follows the order of i = 0, 1, 2,...

Fourth, the base station informs the terminals of the number (N _{real_PDCH} ) of PDCCH currently being used for the CDM. Whenever the value changes, the base station informs the terminals from time to time by using a physical channel, a signaling method, or a broadcasting method.

Fifth, the base station informs all terminals that packet data is being transmitted using the CDM scheme. (This may or may not be used as an option.) To this end, the base station generates a 'CDM indicator' information bit. Here, the 'CDM indicator' is a generic name of information bits that play such a role. The base station informs the terminals of this 'CDM indicator' bit using a physical channel, a signaling method, or a broadcasting method.

In general, the 'CDM indicator' bit only needs to use one bit, and the 'CDM indicator' = 0-> indicates that no CDM is currently running, and the 'CDM indicator' = 1-> currently performed by the CDM It can refer to the meaning.

In the present invention, all terminals can use all PDCCH (i).

The base station providing the above information transmits packet data to terminals according to the following procedure.

That is, the base station selects one packet to be transmitted through transmission scheduling at any point in time (ta), and transmits the control information to PDCCH (0), and the packet is PDCH (0) using Walsh (0). Send it through. Walsh (0) = Walsh (all), unless it is a condition to perform CDM at the same time (ta).

If the CDM is needed at the same time (ta), the corresponding control information is sequentially transmitted to PDCCH (1), PDCCH (2), ..., according to priority, and the corresponding packet is transmitted to Walsh (1). ), Through Walsh (2), PDCH (1), PDCH (2), ..., respectively. After that, if no further CDM is needed at the same time ta, the process proceeds to the next time tb and then performs transmission scheduling again.

That is, when one packet _0 is transmitted through the PDCCH (0), and simultaneously packet_1 to be transmitted to the CDM is scheduled, control information of the packet_1 is transmitted through the PDCCH (1). If the packet_2 to be transmitted to the CDM is scheduled at the same time, the control information of the packet_2 is transmitted through the PDCCH 2.

The terminal receiving the information from the base station receives data transmitted to itself in the following various cases.

First, the terminal does not receive the 'CDM indicator' from the base station, or the 'CDM indicator' is not used in the base station, and also knows only the maximum number of PDCH (N _{max_PDCH} ) that can be used by the base station for the CDM. The CDM indicator is control information indicating whether the CDM is used.

In this case, the terminal always _analyzes N _{max_PDCH} all PDCCHs until it discovers that its data is present through interpretation of control information transmitted through the PDCCH or that all Walsh codes in the Walsh code space have been used. Monitor according to the priority of the PDCCH.

Second, when the 'CDM indicator' is used at the base station, the terminal receives the 'CDM indicator' from the base station, and also knows the maximum number of PDCCH (N _{max_PDCH} ) that the base station can use for the CDM, the terminal ' Continue to check the CDM indicators. If the 'CDM indicator' informs that the CDM is not currently being performed, the terminal monitors only the PDCCH (0). However, if the 'CDM indicator' informs that the CDM is being performed, the terminal may discover that its data is present through the interpretation of control information transmitted through the PDCCH, or that all Walsh codes in the Walsh code space are used up. All PDCCHs are monitored according to the priority of each PDCCH until the fact is known. That is, the terminal continuously stores all PDCCHs until the 'CDM indicator' informs that the CDM is being performed. However, only the PDCCH (0) needs to be monitored.

Third, when the 'CDM indicator' is not used at the base station and the terminal knows the number of PDCCHs (N _{real_PDCH} ) currently being used for the CDM, the terminal can access the CDM through the N _{real_PDCH} without the 'CDM indicator'. You can predict that you are performing. By way of example, '00' means that there is no CDM now and other numbers mean that there is a CDM. In this case, the terminal determines the fact that its own data exists through the interpretation of control information transmitted through the PDCCH, or according to the priority of each PDCCH until it knows that all Walsh codes in the Walsh code space have been used. _{Monitors real_PDCH} PDCCHs.

For example, when using an information bit for indicating N _{real_PDCH} as 2 bits, (00) ₂ monitors only PDCCH (0). (01) ₂ monitors PDCCH (0), PDCCH (1). (10) ₂ monitors only PDCCH (0), PDCCH (1) and PDCCH (2). (11) ₂ monitors all PDCCHs.

In the various cases, if the terminal does not include the information on the length of time of the transmission unit of the PDCH (i) in the information of the PDCCH (i), each terminal may be added, such as a CRC check of the PDCCH (i). By using an appropriate means it is possible to find the time length of the transmission unit of the PDCH (i). Smell out the transmission unit time is for the Blind STE blind rate detection.

In addition, information bits for representing information on Walsh (i) corresponding to the PDCH (i) may be added to the PDCCH (i), and a new control channel (NPDCCH) for this control information may exist.

TDM or CDM / TDM scheme is operated between the terminal receiving the above information and the base station providing the same as shown in FIGS. 3 to 5.

3 is a diagram illustrating an example of a CDM / TDM scheme according to the present invention.

3 is a diagram illustrating a case where CDM is not used, and when N _{max_PDCH} is 4, control information of all terminals is transmitted through PDCCH (0). 3 is the same as the packet data transmission of the conventional TDM scheme.

4A to 4B illustrate another example of a CDM / TDM scheme according to the present invention.

4A to 4B, the base station illustrates a method of transmitting control information of terminals corresponding to the CDM to PDCCHs according to priority at the moment of using the CDM. 4A to 4B, it is assumed that N _{max_PDCH} is 4.

Referring to FIG. 4A, since only TDM is used in the transmission interval (a) and the transmission interval (c), the PDCH (0) corresponding to each PDCCH (0) always uses Walsh (all). However, since only CDM is used in the transmission period (b), Walsh (i) is used for PDCH (i) corresponding to each PDCCH (i). In this (b), the value of N _{real_PDCH} is two.

Referring to FIG. 4B, since only TDM is used in transmission periods (a), (c), and (e), Walsh (0) is always used for PDCH (0) corresponding to each PDCCH (0). However, since only CDM is used in the transmission period (b), Walsh (i) is used for PDCH (i) corresponding to each PDCCH (i). In this (b), the N _{real_PDCH} value is two.

Similarly, since only the CDM is used in the transmission interval (d), the PDCH (i) corresponding to each PDCCH (i) uses Walsh (i). In this (d), N _{real_PDCH} value is 3.

5a to 5c are diagrams showing another example of a CDM / TDM scheme according to the present invention.

5A to 5C show that when CDM is used, the time length of a transmission unit of PDCH (0) can be freely determined. However, when i is greater than 0, the time length of a transmission unit of PDCH (i) is not free. This is an example of the case of operating with.

Referring to FIG. 5A, when CDM is used and i is greater than 0, the time length of a transmission unit of PDCH (i) may be freely determined, but has a constraint that it should be shorter than the transmission unit time length of PDCH (0). An illustration of the.

Referring to FIG. 5B, when CDM is used and i is greater than 0, the time length of the transmission unit of PDCH (i) is shorter than the time length of the transmission unit of PDCH (0) and has a constraint that all should be uniform. It is an illustration of the case.

Referring to FIG. 5C, when CDM is used and i is greater than 0, an exemplary diagram in which the time length of the transmission unit of PDCH (i) has the same constraint as the time length of the transmission unit of PDCH (0) is illustrated. to be.

As described above, the present invention has an effect of reducing the waste of available resources when operating the CDM / TDM. In addition, the present invention has the effect of reducing the heavy use of PDCCHs used for one PDCH.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

Claims (19)

In a mobile communication system in which time division and code division are mixed, Determining priorities of control channels for data reception of terminals; Transmitting control information on packet data to be transmitted through the determined priority control channel; And transmitting the packet data through a transmission channel corresponding to the control channel. The method of claim 1, further comprising providing information on whether the terminal supports the code multiplexing scheme, the maximum number of control channels available, the number of control channels currently being used, and whether the code multiplexing scheme is used. Packet data transmission method in a communication system, characterized in that. 3. The method of claim 2, further comprising: monitoring control channels using the provided information; And receiving the data of the channel transmitted to the user by using the monitoring result. 4. The method of claim 3, wherein a specific bit of the number of control channels currently being used indicates whether to use code multiplexing. 3. The method of claim 2, further comprising Walsh code configuration information of the number of transmission channels available for the maximum number of control channels and priority information of the control channels. 6. The method of claim 5, wherein the Walsh code configuration information is transmitted to terminals through the control channel or a newly defined control channel. Scheduling packets for transmission; Determining whether to perform code multiplexing at the scheduling time; As a result of the determination, when performing code multiplexing, sequentially transmitting control information of packets to be code multiplexed to control channels having priority; And transmitting the scheduled packets through transport channels corresponding to the control channels having the priority. 8. The method of claim 7, further comprising the step of transmitting control information via a specific control channel when code multiplexing is not performed as a result of the determination. 8. The method of claim 7, wherein when the code multiplexing is not performed, the transmission channels transmit packets using all Walsh codes. 8. The method of claim 7, wherein each transmission unit time of the transmission channels is limited to a specific length. The method of claim 10, wherein each transmission unit time of the transmission channels is smaller, smaller, or uniform than a reference transmission channel. Receiving priority information of control channels for receiving data from the system side, usage information of these control channels, and information on whether to use code multiplexing; Monitoring, by the terminal, the control channels according to the information; And receiving the data of the channel transmitted to the terminal according to the monitoring result. 13. The method of claim 12, wherein the control channel usage information includes a maximum number of control channels available in the system and a number of control channels currently in use. 13. The method of claim 12, wherein the terminal does not receive the code multiplexing availability information, or if the code multiplexing is not used in the system, and the terminal knows the maximum number of control channels, the maximum transmission A method of transmitting packet data in a communication system, characterized by monitoring as many control channels as the number of channels. 13. The method of claim 12, wherein the terminal receives code multiplexing availability information and, when the terminal knows the maximum number of control channels, monitors the control channels according to the availability information. . 13. The method of claim 12, wherein when code multiplexing is employed, the terminal monitors all control channels. 13. The method of claim 12, wherein when the code multiplexing is not used, the terminal monitors only a specific control channel. The communication system as claimed in claim 12, wherein when the code multiplexing information is not used and the terminal knows the number of control channels currently being used, the number of control channels is monitored. Packet data transmission method. 13. The method of claim 12, wherein the control channel is monitored until it knows that there is data being received at the terminal or that all Walsh codes have been used.